Tmprss3, a Transmembrane Serine Protease Deficient in Human DFNB8/10 Deafness, Is Critical for Cochlear Hair Cell Survival at the Onset of Hearing

Fasquelle, Lydie; Scott, Hamish S.; Lenoir, Marc; Wang, Jing; Rebillard, Guy; Gaboyard, Sophie; Ventéo, Stéphanie; François, Florence; Mausset-Bonnefont, Anne-Laure; Antonarakis, Stylianos E.; Neidhart, Elizabeth; Chabbert, Christian; Puel, Jean–Luc; Guipponi, Michel; Delprat, Benjamin

doi:10.1074/jbc.m110.190652

Cited by 73 publications

(88 citation statements)

References 33 publications

(34 reference statements)

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“…In Xirp2 −/− mice, the F-actin meshwork of the cuticular plates might be looser or the failure of membrane-cytoskeletal adhesion may allow the extrusion of membrane from weaker spots in the apical surface. A similar phenotype was described in Tmprss3 Y260X mutant mice (Fasquelle et al, 2011) although the protrusions were reported to be kinocilia.…”

Section: Discussionsupporting

confidence: 67%

XIRP2, an Actin-Binding Protein Essential for Inner Ear Hair-Cell Stereocilia

et al. 2015

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SUMMARY Hair cells of the inner ear are mechanoreceptors for hearing and balance, and proteins highly enriched in hair cells may have specific roles in the development and maintenance of the mechanotransduction apparatus. We identified XIRP2/mXinβ as an enriched protein likely to be essential for hair cells. We found that different isoforms of this protein are expressed and differentially located: short splice forms (also called XEPLIN) are targeted more to stereocilia, whereas two long isoforms containing a XIN-repeat domain are in both stereocilia and cuticular plates. Mice lacking the Xirp2 gene developed normal stereocilia bundles, but these degenerated with time: stereocilia were lost and long membranous protrusions emanated from the nearby apical surfaces. At an ultrastructural level, the paracrystalline actin filaments became disorganized. XIRP2 is apparently involved in the maintenance of actin structures in stereocilia and cuticular plates of hair cells, and perhaps in other organs where it is expressed.

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Section: Discussionsupporting

confidence: 67%

XIRP2, an Actin-Binding Protein Essential for Inner Ear Hair-Cell Stereocilia

et al. 2015

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“…Human genetics and loss of function studies in mice have revealed important and surprisingly diverse roles of membrane-anchored serine proteases in mammalian development and postnatal homeostasis. These include placental morphogenesis [4, 5], neural tube closure [6], epithelial tight junction formation [7, 8], auditory and vestibular hair cell survival [9, 10], apical epithelial sodium entry [11], blood pressure [12, 13], iron homeostasis [14-16], male fertility [17, 18], and skin development.…”

Section: Introductionmentioning

confidence: 99%

TMPRSS13 deficiency impairs stratum corneum formation and epidermal barrier acquisition

Madsen

Szabo

Molinolo

et al. 2014

Biochemical Journal

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Membrane-anchored serine proteases serve as important regulators of multiple developmental and homeostatic processes in mammals. Transmembrane protease, serine 13, TMPRSS13 (also known as mosaic serine protease large-form, MSPL), is a membrane-anchored serine protease with unknown biological functions. In this study, we used mice with the Tmprss13 gene disrupted by a β-galactosidase-neomycin fusion gene insertion to study the expression and function of the membrane-anchored serine protease. High levels of Tmprss13 expression were found in the epithelia of the oral cavity, upper digestive tract, and skin. Compatible with this expression pattern, Tmprss13-deficient mice displayed abnormal skin development leading to a compromised barrier function, as measured by trans-epidermal fluid loss rate of newborn mice. The study provides the first biological function for the transmembrane serine protease, TMPRSS13.

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“…Hair cell damage can result from developmental malformations, post-developmental insults (Dror and Avraham, 2010), or late-onset effects of mutations (Fasquelle et al, 2011) of either cochlear (hearing) or vestibular (balance) hair cells. Regardless of etiology, loss of hair cells is irreversible in mammals.…”

Section: Introductionmentioning

confidence: 99%

N-Myc and L-Myc are essential for hair cell formation but not maintenance

2012

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Sensorineural hearing loss results from damage to the hair cells of the organ of Corti and is irreversible in mammals. While hair cell regeneration may prove to be the ideal therapy after hearing loss, prevention of initial hair cell loss could provide even more benefit at a lower cost. Previous studies have shown that the deletion of Atoh1 results in embryonic loss of hair cells while the absence of Barhl1, Gfi1, and Pou4f3 leads to the progressive loss of hair cells in newborn mice. We recently reported that in the early embryonic absence of N-Myc (using Pax2-Cre), hair cells in the organ of Corti develop and remain until at least seven days after birth, with subsequent progressive loss. Thus, N-Myc plays a role in hair cell viability; however, it is unclear if this is due to its early expression in hair cell precursors and throughout the growing otocyst as it functions through proliferation or its late expression exclusively in differentiated hair cells. Furthermore, the related family member L-Myc is mostly co-expressed in the ear, including in differentiated hair cells, but its function has not been studied and could be partially redundant to N-Myc. To test for a long-term function of the Mycs in differentiated hair cells, we generated nine unique genotypes knocking out N-Myc and/or L-Myc after initial formation of hair cells using the well-characterized Atoh1-Cre. We tested functionality of the auditory and vestibular systems at both P21 and four months of age and under the administration of the ototoxic drug cisplatin. We conclude that neither N-Myc nor L-Myc is likely to play important roles in long-term hair cell maintenance. Therefore, it is likely that the late-onset loss of hair cells resulting from early deletion of the Mycs leads to an unsustainable developmental defect.

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Tmprss3, a Transmembrane Serine Protease Deficient in Human DFNB8/10 Deafness, Is Critical for Cochlear Hair Cell Survival at the Onset of Hearing

Cited by 73 publications

References 33 publications

XIRP2, an Actin-Binding Protein Essential for Inner Ear Hair-Cell Stereocilia

XIRP2, an Actin-Binding Protein Essential for Inner Ear Hair-Cell Stereocilia

TMPRSS13 deficiency impairs stratum corneum formation and epidermal barrier acquisition

N-Myc and L-Myc are essential for hair cell formation but not maintenance

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